Isolation and characterization of dnaX and dnaY temperature-sensitive mutants of Escherichia coli

Role of accessory DNA polymerases in DNA replication in Escherichia coli: analysis of the dnaX36 mutator mutant

The dnaX36(TS) mutant of Escherichia coli confers a distinct mutator phenotype characterized by enhancement of transversion base substitutions and certain (-1) frameshift mutations. Here, we have further investigated the possible mechanism(s) underlying this mutator effect, focusing in particular on the role of the various E. coli DNA polymerases. The dnaX gene encodes the tau subunit of DNA polymerase III (Pol III) holoenzyme, the enzyme responsible for replication of the bacterial chromosome. The dnaX36 defect resides in the C-terminal domain V of tau, essential for interaction of tau with the alpha (polymerase) subunit, suggesting that the mutator phenotype is caused by an impaired or altered alpha-tau interaction. We previously proposed that the mutator activity results from aberrant processing of terminal mismatches created by Pol III insertion errors. The present results, including lack of interaction of dnaX36 with mutM, mutY, and recA defects, support our assumption that dnaX36-mediated mutations originate as errors of replication rather than DNA damage-related events. Second, an important role is described for DNA Pol II and Pol IV in preventing and producing, respectively, the mutations. In the system used, a high fraction of the mutations is dependent on the action of Pol IV in a (dinB) gene dosage-dependent manner. However, an even larger but opposing role is deduced for Pol II, revealing Pol II to be a major editor of Pol III mediated replication errors. Overall, the results provide insight into the interplay of the various DNA polymerases, and of tau subunit, in securing a high fidelity of replication.

Genetic evidence for a link between glycolysis and DNA replication

Background

A challenging goal in biology is to understand how the principal cellular functions are integrated so that cells achieve viability and optimal fitness in a wide range of nutritional conditions.

Methodology/Principal Findings

We report here a tight link between glycolysis and DNA synthesis. The link, discovered during an analysis of suppressors of thermosensitive replication mutants in bacterium Bacillus subtilis, is very strong as some metabolic alterations fully restore viability to replication mutants in which a lethal arrest of DNA synthesis otherwise occurs at a high, restrictive, temperature. Full restoration of viability by such alterations was limited to cells with mutations in three elongation factors (the lagging strand DnaE polymerase, the primase and the helicase) out of a large set of thermosensitive mutants affected in most of the replication proteins. Restoration of viability resulted, at least in part, from maintenance of replication protein activity at high temperature. Physiological studies suggested that this restoration depended on the activity of the three-carbon part of the glycolysis/gluconeogenesis pathway and occurred in both glycolytic and gluconeogenic regimens. Restoration took place abruptly over a narrow range of expression of genes in the three-carbon part of glycolysis. However, the absolute value of this range varied greatly with the allele in question. Finally, restoration of cell viability did not appear to be the result of a decrease in growth rate or an induction of major stress responses.

Conclusions/Significance

Our findings provide the first evidence for a genetic system that connects DNA chain elongation to glycolysis. Its role may be to modulate some aspect of DNA synthesis in response to the energy provided by the environment and the underlying mechanism is discussed. It is proposed that related systems are ubiquitous.

Functional defects in transfer RNAs lead to the accumulation of ribosomal RNA precursors

Normal expression and function of transfer RNA (tRNA) are of paramount importance for translation. In this study, we show that tRNA defects are also associated with increased levels of immature ribosomal RNA (rRNA). This association was first shown in detail for a mutant strain that underproduces tRNA(Arg2) in which unprocessed 16S and 23S rRNA levels were increased several-fold. Ribosome profiles indicated that unprocessed 23S rRNA in the mutant strain accumulates in ribosomal fractions that sediment with altered mobility. Underproduction of tRNA(Arg2) also resulted in growth defects under standard laboratory growth conditions. Interestingly, the growth and rRNA processing defects were attenuated when cells were grown in minimal medium or at low temperatures, indicating that the requirement for tRNA(Arg2) may be reduced under conditions of slower growth. Other tRNA defects were also studied, including a defect in RNase P, an enzyme involved in tRNA processing; a mutation in tRNA(Trp) that results in its degradation at elevated temperatures; and the titration of the tRNA that recognizes rare AGA codons. In all cases, the levels of unprocessed 16S and 23S rRNA were enhanced. Thus, a range of tRNA defects can indirectly influence translation via effects on the biogenesis of the translation apparatus.

Mutator mutants of Escherichia coli carrying a defect in the DNA polymerase III tau subunit

To investigate the possible role of accessory subunits of Escherichia coli DNA polymerase III holoenzyme (HE) in determining chromosomal replication fidelity, we have investigated the role of the dnaX gene. This gene encodes both the tau and gamma subunits of HE, which play a central role in the organization and functioning of HE at the replication fork. We find that a classical, temperature-sensitive dnaX allele, dnaX36, displays a pronounced mutator effect, characterized by an unusual specificity: preferential enhancement of transversions and -1 frameshifts. The latter occur predominantly at non-run sequences. The dnaX36 defect does not affect the gamma subunit, but produces a tau subunit carrying a missense substitution (E601K) in its C-terminal domain (domain V) that is involved in interaction with the Pol III alpha subunit. A search for new mutators in the dnaX region of the chromosome yielded six additional dnaX mutators, all carrying a specific tau subunit defect. The new mutators displayed phenotypes similar to dnaX36: strong enhancement of transversions and frameshifts and only weak enhancement for transitions. The combined findings suggest that the tau subunit of HE plays an important role in determining the fidelity of the chromosomal replication, specifically in the avoidance of transversions and frameshift mutations.

Differential effects of cisplatin and MNNG on dna mutants of Escherichia coli

DNA mismatch repair (MMR) in mammalian cells or Escherichia coli dam mutants increases the cytotoxic effects of cisplatin and N-methyl-N'-nitro-N-nitrosoguanidine (MNNG). We found that, unlike wildtype, the dnaE486 (alpha catalytic subunit of DNA polymerase III holoenzyme) mutant, and a DnaX (clamp loader subunits) over-producer, are sensitive to cisplatin but resistant to MNNG at the permissive temperature for growth. Survival of dam-13 dnaN159 (beta sliding clamp) bacteria to cisplatin was significantly less than dam cells, suggesting decreased MMR, which may be due to reduced MutS-beta clamp interaction. We also found an elevated spontaneous mutant frequency to rifampicin resistance in dnaE486 (10-fold), dnaN159 (35-fold) and dnaX36 (10-fold) strains. The mutation spectrum in the dnaN159 strain was consistent with increased SOS induction and not indicative of MMR deficiency.

Discovery and characterization of the cryptic psi subunit of the pseudomonad DNA replicase

We previously reconstituted a minimal DNA replicase from Pseudomonas aeruginosa consisting of alpha and epsilon (polymerase and editing nuclease), beta (processivity factor), and the essential tau, delta, and delta' components of the clamp loader complex (Jarvis, T., Beaudry, A., Bullard, J., Janjic, N., and McHenry, C. (2005) J. Biol. Chem. 280, 7890-7900). In Escherichia coli DNA polymerase III holoenzyme, chi and Psi are tightly associated clamp loader accessory subunits. The addition of E. coli chiPsi to the minimal P. aeruginosa replicase stimulated its activity, suggesting the existence of chi and Psi counterparts in P. aeruginosa. The P. aeruginosa chi subunit was recognizable from sequence similarity, but Psi was not. Here we report purification of an endogenous replication complex from P. aeruginosa. Identification of the components led to the discovery of the cryptic Psi subunit, encoded by holD. P. aeruginosa chi and Psi were co-expressed and purified as a 1:1 complex. P. aeruginosa chiPsi increased the specific activity of tau(3)deltadelta' 25-fold and enabled the holoenzyme to function under physiological salt conditions. A synergistic effect between chiPsi and single-stranded DNA binding protein was observed. Sequence similarity to P. aeruginosa Psi allowed us to identify Psi subunits from several other Pseudomonads and to predict probable translational start sites for this protein family. This represents the first identification of a highly divergent branch of the Psi family and confirms the existence of Psi in several organisms in which Psi was not identifiable based on sequence similarity alone.

Reconstitution of a minimal DNA replicase from Pseudomonas aeruginosa and stimulation by non-cognate auxiliary factors

DNA polymerase III holoenzyme is responsible for chromosomal replication in bacteria. The components and functions of Escherichia coli DNA polymerase III holoenzyme have been studied extensively. Here, we report the reconstitution of replicase activity by essential components of DNA polymerase holoenzyme from the pathogen Pseudomonas aeruginosa. We have expressed and purified the processivity factor (beta), single-stranded DNA-binding protein, a complex containing the polymerase (alpha) and exonuclease (epsilon) subunits, and the essential components of the DnaX complex (tau(3)deltadelta'). Efficient primer elongation requires the presence of alphaepsilon, beta, and tau(3)deltadelta'. Pseudomonas aeruginosa alphaepsilon can substitute completely for E. coli polymerase III in E. coli holoenzyme reconstitution assays. Pseudomonas beta and tau(3)deltadelta' exhibit a 10-fold lower activity relative to their E. coli counterparts in E. coli holoenzyme reconstitution assays. Although the Pseudomonas counterpart to the E. coli psi subunit was not apparent in sequence similarity searches, addition of purified E. coli chi and psi (components of the DnaX complex) increases the apparent specific activity of the Pseudomonas tau(3)deltadelta' complex approximately 10-fold and enables the reconstituted enzyme to function better under physiological salt conditions.

The Escherichia coli argU10(Ts) phenotype is caused by a reduction in the cellular level of the argU tRNA for the rare codons AGA and AGG

The Escherichia coli argU10(Ts) mutation in the argU gene, encoding the minor tRNA(Arg) species for the rare codons AGA and AGG, causes pleiotropic defects, including growth inhibition at high temperatures, as well as the Pin phenotype at 30 degrees C. In the present study, we first showed that the codon selectivity and the arginine-accepting activity of the argU tRNA are both essential for complementing the temperature-sensitive growth, indicating that this defect is caused at the level of translation. An in vitro analysis of the effects of the argU10(Ts) mutation on tRNA functions revealed that the affinity with elongation factor Tu-GTP of the argU10(Ts) mutant tRNA is impaired at 30 and 43 degrees C, and this defect is more serious at the higher temperature. The arginine acceptance is also impaired significantly but to similar extents at the two temperatures. An in vivo analysis of aminoacylation levels showed that 30% of the argU10(Ts) tRNA molecules in the mutant cells are actually deacylated at 30 degrees C, while most of the argU tRNA molecules in the wild-type cells are aminoacylated. Furthermore, the cellular level of this mutant tRNA is one-tenth that of the wild-type argU tRNA. At 43 degrees C, the cellular level of the argU10(Ts) tRNA is further reduced to a trace amount, while neither the cellular abundance nor the aminoacylation level of the wild-type argU tRNA changes. We concluded that the phenotypic properties of the argU10(Ts) mutant result from these reduced intracellular levels of the tRNA, which are probably caused by the defective interactions with elongation factor Tu and arginyl-tRNA synthetase.

Overexpression of an mRNA dependent on rare codons inhibits protein synthesis and cell growth

lambda's int gene contains an unusually high frequency of the rare arginine codons AGA and AGG, as well as dual rare Arg codons at three positions. Related work has demonstrated that Int protein expression depends on the rare AGA tRNA. Strong transcription of the int mRNA with a highly efficient ribosome-binding site leads to inhibition of Int protein synthesis, alteration of the overall pattern of cellular protein synthesis, and cell death. Synthesis or stability of int and ampicillin resistance mRNAs is not affected, although a portion of the untranslated int mRNA appears to be modified in a site-specific fashion. These phenotypes are not due to a toxic effect of the int gene product and can be largely reversed by supplementation of the AGA tRNA in cells which bear plasmids expressing the T4 AGA tRNA gene. This indicates that depletion of the rare Arg tRNA due to ribosome stalling at multiple AGA and AGG codons on the overexpressed int mRNA underlies all of these phenomena. It is hypothesized that int mRNA's effects on protein synthesis and cell viability relate to phenomena involved in lambda phage induction and excision.

Mutations in Escherichia coli dnaA which suppress a dnaX(Ts) polymerization mutation and are dominant when located in the chromosomal allele and recessive on plasmids

Extragenic suppressor mutations which had the ability to suppress a dnaX2016(Ts) DNA polymerization defect and which concomitantly caused cold sensitivity have been characterized within the dnaA initiation gene. When these alleles (designated Cs, Sx) were moved into dnaX+ strains, the new mutants became cold sensitive and phenotypically were initiation defective at 20 degrees C (J.R. Walker, J.A. Ramsey, and W.G. Haldenwang, Proc. Natl. Acad. Sci. USA 79:3340-3344, 1982). Detailed localization by marker rescue and DNA sequencing are reported here. One mutation changed codon 213 from Ala to Asp, the second changed Arg-432 to Leu, and the third changed codon 435 from Thr to Lys. It is striking that two of the three spontaneous mutations occurred in codons 432 and 435; these codons are within a very highly conserved, 12-residue region (K. Skarstad and E. Boye, Biochim. Biophys. Acta 1217:111-130, 1994; W. Messer and C. Weigel, submitted for publication) which must be critical for one of the DnaA activities. The dominance of wild-type and mutant alleles in both initiation and suppression activities was studied. First, in initiation function, the wild-type allele was dominant over the Cs, Sx alleles, and this dominance was independent of location. That is, the dnaA+ allele restored growth to dnaA (Cs, Sx) strains at 20 degrees C independently of which allele was present on the plasmid. The dnaA (Cs, Sx) alleles provided initiator function at 39 degrees C and were dominant in a dnaA(Ts) host at that temperature. On the other hand, suppression was dominant when the suppressor allele was chromosomal but recessive when it was plasmid borne. Furthermore, suppression was not observed when the suppressor allele was present on a plasmid and the chromosomal dnaA was a null allele. These data suggest that the suppressor allele must be integrated into the chromosome, perhaps at the normal dnaA location. Suppression by dnaA (Cs, Sx) did not require initiation at oriC; it was observed in strains deleted of oriC and which initiated at an integrated plasmid origin.

The Escherichia coli DNA polymerase III holoenzyme contains both products of the dnaX gene, tau and gamma, but only tau is essential

The replicative polymerase of Escherichia coli, DNA polymerase III, consists of a three-subunit core polymerase plus seven accessory subunits. Of these seven, tau and gamma are products of one replication gene, dnaX. The shorter gamma is created from within the tau reading frame by a programmed ribosomal -1 frameshift over codons 428 and 429 followed by a stop codon in the new frame. Two temperature-sensitive mutations are available in dnaX. The 2016(Ts) mutation altered both tau and gamma by changing codon 118 from glycine to aspartate; the 36(Ts) mutation affected the activity only of tau because it altered codon 601 (from glutamate to lysine). Evidence which indicates that, of these two proteins, only the longer tau is essential includes the following. (i) The 36(Ts) mutation is a temperature-sensitive lethal allele, and overproduction of wild-type gamma cannot restore its growth. (ii) An allele which produced tau only could be substituted for the wild-type chromosomal gene, but a gamma-only allele could not substitute for the wild-type dnaX in the haploid state. Thus, the shorter subunit gamma is not essential, suggesting that tau can be substitute for the usual function(s) of gamma. Consistent with these results, we found that a functional polymerase was assembled from nine pure subunits in the absence of the gamma subunit. However, the possibility that, in cells growing without gamma, proteolysis of tau to form a gamma-like product in amounts below the Western blot (immunoblot) sensitivity level cannot be excluded.

Novel in-frame two codon translational hop during synthesis of bovine placental lactogen in a recombinant strain of Escherichia coli

A recombinant Escherichia coli strain was constructed for the overexpression of bovine placental lactogen (bPL), using a bPL structural gene containing 9 of the rare arginine codons AGA and AGG. When high level bPL synthesis was induced in this strain, cell growth was inhibited and bPL accumulated to less than 10% of total cell protein. In addition, about 2% of the recombinant bPL produced from this strain exhibited an altered trypsin digestion pattern. Amino acid residues 74 through 109 normally produce 2 tryptic peptides, but the altered form of bPL lacked these two peptides and instead had a new peptide which was missing arginine residue 86 and one of the two flanking leucine residues. The codon for arginine residue 86 was AGG and the codons for the flanking leucine residues 85 and 87 were TTG. When 5 of the 9 AGA and AGG codons in the bPL structural gene were changed to more preferred arginine codons, cell growth was not inhibited and bPL accumulated to about 30% of total cell protein. When bPL was purified from this modified strain, which included changing the arginine codon at position 86 from AGG to CGT, none of the altered form of bPL was produced. These observations are consistent with a model in which translational pausing occurs at the arginine residue 86 AGG codon because the corresponding arginyl-tRNA species is reduced by the high level of bPL synthesis, and a translational hop occurs from the leucine residue 85 TTG codon to the leucine residue 87 TTG codon. This observation represents the first report of an error in protein synthesis due to an in-frame translational hop within an open reading frame.

Transcriptional organization of the Escherichia coli dnaX gene

We have determined the transcriptional organization of the Escherichia coli dnaX gene, the structural gene for both the gamma and tau subunits of DNA polymerase III holoenzyme. By S1 nuclease protection and primer extension mapping of transcripts encoding the dnaX products, one primary promoter of dnaX has been identified that initiates transcription 37 nucleotides upstream from the first codon. dnaX resides in an operon with two recently sequenced genes, orf12, encoding an unidentified product, and recR, the structural gene for a protein involved in the recF pathway of recombination. Under conditions of balanced growth, a very small amount of transcription from the upstream apt promoter (less than 5%) contributes to the expression of tau and gamma, too low for apt to be considered to be on an operon with dnaX, orf12, and recR are transcribed from an independent promoter as well as from the dnaX promoter, providing a mechanism for orf12 and recR to be regulated independent of dnaX. Transcription of the dnaX-orf12-recR operon is terminated upstream from the previously characterized heat shock gene htpG. The dnaX and orf12-recR promoters, cloned into a promoter detection vector, efficiently direct the expression of the downstream reporter gene, lacZ. These results extend our knowledge of the genetic and transcriptional organization of this region of the E. coli chromosome. The transcriptional organization has been defined as follows: apt, dnaX-orf12-recR, htpG. All of these genes are transcribed in the clockwise direction and only dnaX, orf12 and recR are contained in the dnaX operon.

Frameshift suppression at tandem AGA and AGG codons by cloned tRNA genes: assigning a codon to argU tRNA and T4 tRNA(Arg)

Arginine is coded for by CGN (N = G, A, U, C), AGA and AGG. In Escherichia coli there is little tRNA for AGA and AGG and the use of these codons is strongly avoided in virtually all genes. Recently, we demonstrated that the presence of tandem AGA or AGG codons in mRNA causes frameshifts with high frequency. Here, we show that phaseshifts can be suppressed when cells are transformed with the gene for tRNA(T4Arg) or E. coli tRNA(argU,Arg) demonstrating that such errors are the result of tRNA depletion. Bacteriophage T4 encoded tRNA(Arg) (anticodon UCU) corrects shifts at AGA-AGA but not at AGG-AGG, suggesting that this tRNA can only read AGA. Similarly, comparison of the translational efficiencies in an argU (Ts) mutant and in its isogenic wild type parent indicates that argU tRNA (anticodon UCU) reads AGA but not AGG. An argU (Ts) mutant barely reads through AGA-AGA at 42 degrees C but translation of AGG-AGG is hardly, if at all, affected. Overexpression of argU+ relaxes the codon specificity. The thermosensitive mutant in argU, previously called dnaY because it is defective in DNA replication, can be complemented for growth by the gene for tRNA(T4Arg). This implies that the sole function of the argU gene product is to sustain protein synthesis and that its role in replication is probably indirect.

A minor arginine tRNA mutant limits translation preferentially of a protein dependent on the cognate codon

The Escherichia coli argU gene encodes a rare arginine tRNA (anticodon UCU) that translates the similarly rare AGA codon. The argU10(Ts) mutation is a transition that changes the first nucleotide of the mature tRNA from G to A, presumably destabilizing the acceptor stem. This mutation, when present in haploid condition in the chromosome, reduces the growth rate at 30 degrees C and results in cessation of growth after 60 to 90 min at 43 degrees C. The mutation also preferentially limits (compared with total protein synthesis) translation of an induced gene that depends on five AGA codons, i.e., the lambda cI repressor gene. Translation of another inducible protein, beta-galactosidase, which does not involve AGA codons, was inhibited to a much lesser extent. The chromosomal argU(Ts) mutation also confers the Pin phenotype, that is, loss of ability of the host, as a P2 lysogen, to inhibit growth of bacteriophage lambda, probably the result of reduced translation of the P2 old gene, which contains five AGA codons (E. Haggård-Ljungquist, V. Barreiro, R. Calendar, D. M. Kurnit, and H. Cheng, Gene 85:25-33, 1989).

The gamma subunit of DNA polymerase III holoenzyme of Escherichia coli is produced by ribosomal frameshifting

The tau and gamma subunits of DNA polymerase III holoenzyme are both products of the dnaX gene. Since tau and gamma are required as stoichiometric components of the replicative complex, a mechanism must exist for the cell to coordinate their synthesis and ensure that both subunits are present in an adequate quantity and ratio for assembly. We have proposed that gamma is produced by a translational frameshift event. In this report, we describe the use of dnaX-lacZ fusions in all three reading frames to demonstrate that gamma, the shorter product of dnaX, is generated by ribosomal frameshifting to the -1 reading frame of the mRNA within an oligo(A) sequence that is followed by a sequence predicted to form a stable secondary structure. Immediately after frameshifting a stop codon is encountered, leading to translational termination. Mutagenesis of the oligo(A) sequence abolishes frameshifting, and partial disruption of the predicted distal secondary structure severely impairs the efficiency. Comparison of the expression of lacZ fused to dnaX distal to the site of frameshifting in the -1 and 0 reading frames indicates that the efficiency of frameshifting is approximately 40%.

Nucleotide sequence of the region encompassing the int gene of a cryptic prophage and the dna Y gene flanked by a curved DNA sequence of Escherichia coli K12

The nucleotide sequence of a 2.5 kb region encompassing a curved DNA segment (BENT-9) randomly cloned from the total Escherichia coli chromosome was determined. This region was found to contain the dna Y gene encoding a transfer RNA. The curved DNA structure was demonstrated to be located just upstream of the dna Y promoter. The results of sequencing further revealed that the int gene of a cryptic prophage, qsr', which has been shown to be present in the E. coli genome, is located next to the dna Y gene.

Characterization of the cryptic lambdoid prophage DLP12 of Escherichia coli and overlap of the DLP12 integrase gene with the tRNA gene argU

The argU (dnaY) gene of Escherichia coli is located, in clockwise orientation, at 577.5 kilobases (kb) on the chromosome physical map. There was a cryptic prophage spanning the 2 kb immediately downstream of argU that consisted of sequences similar to the phage P22 int gene, a portion of the P22 xis gene, and portions of the exo, P, and ren genes of bacteriophage lambda. This cryptic prophage was designated DLP12, for defective lambdoid prophage at 12 min. Immediately clockwise of DLP12 was the IS3 alpha 4 beta 4 insertion element. The argU and DLP12 int genes overlapped at their 3' ends, and argU contained sequence homologous to a portion of the phage P22 attP site. Additional homologies to lambdoid phages were found in the 25 kb clockwise of argU. These included the cryptic prophage qsr' (P. J. Highton, Y. Chang, W. R. Marcotte, Jr., and C. A. Schnaitman, J. Bacteriol. 162:256-262, 1985), a sequence homologous to a portion of lambda orf-194, and an attR homolog. Inasmuch as the DLP12 att int xis exo P/ren region, the qsr' region, and homologs of orf-194 and attR were arranged in the same order and orientation as the lambdoid prophage counterparts, we propose that the designation DLP12 be applied to all these sequences. This organization of the DLP12 sequences and the presence of the argU/DLP12 int pair in several E. coli strains and closely related species suggest that DLP12 might be an ancestral lambdoid prophage. Moreover, the presence of similar sequences at the junctions of DLP12 segments and their phage counterparts suggests that a common mechanism could have transferred these DLP12 segments to more recent phages.

Actively replicating nucleoids influence positioning of division sites in Escherichia coli filaments forming cells lacking DNA

The positioning of constrictions in Escherichia coli filaments pinching off anucleate cells was analyzed by fluorescence microscopy of dnaX(Ts), dnaX(Ts) sfiA, dnaA46(Ts), gyrA(Am) supF(Ts), and gyrB(Ts) mutants. In filaments with actively replicating nucleoids, constrictions were positioned close to the nucleoid, whereas in nonreplicating filaments, positioning of constrictions within the anucleate region was nearly random. We conclude that constriction positioning depends in an unknown way on nucleoid replication activity.

The Escherichia coli cell division mutation ftsM1 is in serU

The ftsM1 mutation is believed to be in a gene implicated in the regulation of cell division in Escherichia coli because it displayed the lon mutation phenotypes. In this study, we show that this mutation is located in serU, a gene which codes for tRNA(Ser)2, and has the phenotypes of the serU allele supH. Both ftsM1 and supH suppressed the leuB6 and ilvD145 missense mutations, and both conferred temperature and UV light irradiation sensitivity to the harboring cells. Cells which carried the ftsM1 mutation or the supH suppressor had very low colony-forming abilities on salt-free L agar, and this phenotype was almost completely abolished by the presence of plasmids bearing the ftsZ+ gene. Furthermore, sensitivity of the mutant cells to UV irradiation was also markedly diminished when they carried a ftsZ+-bearing plasmid. These results suggest that supH-containing cells have reduced FtsZ activities, in accordance with their displaying the phenotypes of the lon mutant cells. The possibility that ftsM1 (supH) is functionally involved in the biosynthesis of a specific protein which affects cell division is discussed.

Cloning and characterization of an albicidin resistance gene from Klebsiella oxytoca

A DNA fragment containing a gene for resistance to the antibiotic albicidin was isolated from Klebsiella oxytoca and shown to be expressed in Escherichia coli, where it also protected bacteriophage T7 replication from inhibition by albicidin. In vivo translation analysis demonstrated that the cloned 2.2kb DNA fragment coded for a 36 kiloDalton (kD) protein and a 25kD protein. The DNA sequence was determined for a 654-base-pair open reading frame contained within a 1.2kb subcloned DNA fragment encoding albicidin resistance. The predicted molecular weight of the polypeptide translated from the open reading frame was 25.8kD. A putative Shine-Dalgarno sequence precedes the open reading frame but a potential promoter sequence was not detected. A possible rho-independent transcription termination signal was found directly following the stop codon. The functional protein for albicidin resistance was isolated and purified. Both the molecular weight and NH2-terminal amino acid sequence of this protein correspond with that predicted from the DNA sequence of the open reading frame. The cloned albicidin resistance gene had no effect on the tsx (nupA) nucleoside uptake gene associated with spontaneous albicidin resistance in E. coli; also, it did not complement any of a range of E. coli DNAts mutants at restrictive temperatures. The cloned resistance gene product remained intracellular in exponential cultures of K. oxytoca and E. coli. Cell-free extracts from E. coli containing the resistance gene protected a sensitive strain of E. coli from inhibition by albicidin, as did the purified albicidin resistance protein. The mechanism of this albicidin resistance protein involved binding to albicidin to form a complex without antibiotic activity, but without catalysing further chemical modification of the antibiotic.

Sequence analysis of the Escherichia coli dnaE gene

We have determined the sequence of a 4,350-nucleotide region of the Escherichia coli chromosome that contains dnaE, the structural gene for the alpha subunit of DNA polymerase III holoenzyme. The dnaE gene appeared to be part of an operon containing at least three other genes: 5'-lpxB-ORF23-dnaE-ORF37-3' (ORF, open reading frame). The lpxB gene encodes lipid A disaccharide synthase, an enzyme essential for cell growth and division (M. Nishijima, C.E. Bulawa, and C.R.H. Raetz, J. Bacteriol. 145:113-121, 1981). The termination codons of lpxB and ORF23 overlapped the initiation codons of ORF23 and dnaE, respectively, suggesting translational coupling. No rho-independent transcription termination sequences were observed. A potential internal transcriptional promoter was found preceding dnaE. Deletion of the -35 region of this promoter abolished dnaE expression in plasmids lacking additional upstream sequences. From the deduced amino acid sequence, alpha had a molecular weight of 129,920 and an isoelectric point of 4.93 for the denatured protein. ORF23 encoded a more basic protein (pI 7.11) with a molecular weight of 23,228. In the accompanying paper (D.N. Crowell, W.S. Reznikoff, and C.R.H. Raetz, J. Bacteriol. 169:5727-5734, 1987), the sequence of the upstream region that contains lpxA and lpxB is reported.

sub, a host mutation that specifically allows growth of replication-deficient gene B mutants of coliphage P2

Bacteriophage P2 normally requires the products of its early genes A and B for lytic growth in its host, Escherichia coli C. A host mutation, sub-1, which allows P2 to grow without a functional B gene product is described. The sub-1 mutation is recessive and maps at approximately 10 min on the E. coli genetic map.

Determination of the precise location and orientation of the Escherichia coli dnaE gene

The minimal region required for expression of the dnaE gene of Escherichia coli has been determined relative to a detailed restriction endonuclease map. This has been accomplished by analysis of Bal 31 exonuclease-generated deletions from the termini of the E. coli DNA contained in plasmid pMWE303 , a plasmid that we have previously demonstrated to contain the dnaE gene (M. M. Welch and C. S. McHenry , J. Bacteriol . 152:351-356, 1982). The competence of these deletion-containing plasmids in expressing the alpha subunit of DNA polymerase III holoenzyme has been determined by their ability both to complement a dnaE mutant and to direct the synthesis of a complete alpha subunit. The carboxyl-terminal coding region of dnaE has been identified through the detection of partial alpha polypeptides encoded by plasmids containing deletions from one end of the gene. This approach has permitted the precise determination of both termini of the dnaE gene and the determination of the orientation of the gene within the E. coli chromosome.

The dnaX gene encodes the DNA polymerase III holoenzyme tau subunit, precursor of the gamma subunit, the dnaZ gene product

The E. coli dnaX and dnaZ gene products, essential for E. coli DNA replication, serve in chain elongation. Both genes, located at 10.4 min and previously cloned into a lambda vector and a ColE1 plasmid, were subcloned into pBR322 (pMK212). The coding region for the dnaX and dnaZ genes was localized to a 2.2-kb segment by deletion analysis of pMK212. The products of dnaX and dnaZ genes were identified as 78 kd and 52 kd polypeptides, respectively, by using maxicells bearing deletion clones of pMK212. Peptide mapping after limited proteolysis showed that the dnaZ gene product (52 kd) is a part of the dnaX gene product (78 kd), thus accounting for the coding capacity of the 2.2 kb region for both the dnaX and dnaZ genes. The dnaX gene product appears to be the tau subunit of DNA polymerase III holoenzyme; the dnaZ gene product is confirmed as the gamma subunit of the holoenzyme.

Cloning of the Escherichia coli dnaZX region and identification of its products

The Escherichia coli DNA replication genes dnaZ and dnaX have previously been localized very near each other at 10.4 to 10.5 min on the chromosome map. These genes were cloned from a dnaZ+X+ plasmid of the Clarke and Carbon collection by identifying complementing fragments and both were located on a 2.1 kilobase pair (kb) fragment. The organization of the Z and X genes was investigated by Tn5 mutagenesis of a Z+X+ plasmid. Insertions which abolished Z or X complementing activity were mapped by restriction enzyme analysis within the 2.1 kb fragment. With the exception of one atypical insertion, all the insertions inactivated both Z and X complementation. The protein products of the dnaZ-dnaX region were labelled in minicells containing dnaZ+X+ and dnaZX::Tn5 plasmids. The 2.1 kb ZX region (which has a maximum coding capacity of 77,000 daltons of protein in a single reading frame) directed the synthesis of two proteins, one of 75,000 daltons, designated dnaX, and another of 56,500 daltons, designated dnaZ. Tn5 insertion into the ZX region interrupted the synthesis of these proteins; the detection of truncated fragments of dnaX determined the direction of transcription. In vitro, using a coupled transcription-translation system dependent on plasmid DNA, synthesis of the 75,000 dalton dnaX protein was demonstrated, but there was no detectable synthesis of the smaller dnaZ protein. Probably, therefore, the 75,000 dalton dnaX protein is cleaved in vivo to generate the dnaZ protein. It is possible that the 75,000 dalton product is the tau subunit of DNA polymerase III because they migrated similarly in electrophoresis.

Overproduction of Escherichia coli replication proteins by the use of runaway-replication plasmids

A derivative of the runaway-replication plasmid was constructed. This plasmid, pSY343, has the gene for kanamycin resistance and single sites for EcoRI, BamHI, HindIII, KpnI, and XhoI that can be used as cloning sites without inactivating the kanamycin resistance gene or the replication genes. Three replication genes of Escherichia coli were cloned on the plasmid. The activity of dnaA, dnaZ, and ssb gene products were 200-, 90-, and 60-fold greater, respectively, in the cells containing these plasmids than in normal cells.

Physiological properties of cold-sensitive suppressor mutations of a temperature-sensitive dnaZ mutant of Escherichia coli

Suppressors of a temperature-sensitive dnaZ polymerization mutant of Escherichia coli have been identified by selecting temperature-insensitive revertants. Those suppressed strains which concomitantly became cold sensitive were chosen for further study. Intragenic suppressor mutations, which caused cold-sensitive defects in DNA polymerization, were located in dnaZ by transduction with lambda dnaZ+ phages. Extragenic suppressor mutations were mapped within the initiation gene dnaA. These suppressor-containing strains were defective in initiation at low temperature as determined by measurements of DNA synthesis in vivo and in toluene-treated cells. The occurrence of suppressor mutations of dnaZ(Ts) within the dnaA gene is considered evidence that the dnaA and dnaZ products interact in vivo. A second indication of a dnaA-dnaZ protein-protein interaction was provided by the observation that the introduction of additional copies of the dnaZ+ gene into a strain carrying the dnaA suppressor mutation was lethal [whether the strain was dnaZ+ or dnaZ(Ts)].

Interactions of DNA replication factors in vivo as detected by introduction of suppressor alleles of dnaA into other temperature-sensitive dna mutants

Suppressor mutations located within dnaA can suppress the temperature sensitivity of a dnaZ polymerization mutant, indicating in vivo interaction of the products of these genes. The suppressor allele of dnaA [designated dnaA(SUZ, Cs)] could not be introduced, even at the permissive temperature, by transduction into temperature-sensitive (Ts) dnaC or dnaG recipients; it was transduced into dnaB(Ts) and dnaE(Ts) strains but at very low frequency. Recipient cells which were dnaA+ dnaE(Ts) were killed by the incoming dnaA(SUZ, Cs) allele, and it is presumed that combinations of dnaA(SUZ, Cs) with dnaB(Ts), dnaC(Ts), or dnaG(Ts) are lethal also. In one specific case, the lethality required the presence of three alleles: the incoming dnaA suppressor mutation, the resident dnaA+ gene, and the dnaB(Ts) gene. This was shown by the fact that dnaB(Ts) could readily be introduced into a dnaA(SUZ, Cs) dnaB+ recipient. That is, in the absence of dnaA+, the dnaA suppressor and dnaB(Ts) double mutant was stable. One model to explain these results proposes that the dnaA protein functions not only in initiation but also in the replication complex which contains multiple copies of dnaA and other replication factors.

Cloning and identification of the product of the dnaE gene of Escherichia coli

We successively subcloned the dnaE gene of Escherichia coli into pBR322, resulting in a plasmid that contains 4.6 kilobases of E. coli DNA. This plasmid can complement a dnaE temperature-sensitive mutation. A restriction map of the dnaE gene and the surrounding 10.7-kilobase region of the E. coli chromosome was determined. A unique HindIII restriction endonuclease site within the cloned segment of DNA was identified as a site required for expression of the dnaE gene. By using the maxicell plasmid-directed protein synthesizing system, we demonstrated that dnaE codes for the alpha subunit of DNA polymerase III.

The Escherichia coli dnaW mutation is an allele of the adk gene

A dnaW mutant, isolated on the basis of inability to effect conjugal DNA transfer at high temperature, has been shown by complementation and enzyme assay to be defective in the adk (adenylate kinase; EC 2.7.4.3) locus. The adk mutant, known to have reduced ATP concentration at the nonpermissive temperature (Cousin and Belaich 1966), was used to demonstrate a donor energy requirement for stable aggregate formation and for chromosome transfer in conjugation.

Host requirements for growth of lambda-P22 hybrid in Escherichia coli

The requirements for growth of bacteriophage lambda containing the deoxyribonucleic acid replication region from Salmonella phage P22 were determined in a burst size experiment. The products of genes dnaE, dnaJ, dnaK, dnaY, dnaZ, and seg were required, but not the products of genes dnaA, dnaB, dnaC, and dnaX. This lambda-P22 hybrid phage was also dependent on polA for growth at 32 degrees C.

The delta subunit of Escherichia coli DNA polymerase III holoenzyme is the dnaX gene product

The delta subunit of DNA polymerase III holoenzyme has been purified extensively with an assay for phi X174 DNA synthesis using core (pol III) and beta and gamma subunits. Either the purified delta subunit or the purified DNA polymerase III holoenzyme can complement a defective enzyme fraction from the conditional replication mutant SG133 described by Sevastopoulos et al. [Sevastopoulas, C.G., Wehr, C.T. & Glaser, D. A. (1977) Proc. Natl. Acad. Sci. USA 74, 3485-3489]. It has been established by Henson et al. [Henson, J.M., Chu, H., Irwin, C.A. & Walker, J.R. (1979) Genetics 92, 1,41-1059] that SG133 has two temperature-sensitive mutations, called dnaX and dnaY. The crude enzyme source from dnaX can be complemented by the delta subunit and by DNA polymerase III holoenzyme. By contrast, the core DNA polymerase III and the beta and gamma subunits are unable to complement this defective enzyme fraction. Thus, the delta subunit of DNA polymerase III holoenzyme appears to be the dnaX gene product of Escherichia coli.